1. NUCLEAR CHAIN REACTION
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Semester Fall 2020
Date ( Dec-1st-2020)
Submitted by : Syed Hammad Ali ( 19012510-085)
Program : MSc-III / D
Course Title : Nuclear Physics
Course Code : PHY-493
Department of Physics
University of Gujrat

2. NUCLEAR CHAIN
REACTION
Nuclear Fission Reaction
Controlled Chain
Reaction
Uncontrolled
Chain Reaction
Advantages Disadvantages
Explosion

3. What is chain reaction?
• A chain reaction is a chemical process in which products themselves promote or spread the reaction.
• A self-sustained reaction or a series of reaction caused by the previous one.
• For example:
• Burning of match stick when placed in series.
• Falling of dominos placed on trajectory.

4. Nuclear Chain Reaction
• The chain reaction in which bombardment of nucleus involves is called nuclear chain reaction.
• One single nuclear reaction that causes one or more than one consecutive nuclear reactions and thus leads to the
happening of a self-propagating series of these reactions.
• This process involves bombardment of nucleus of any heavy element by neutrons called fission process or reaction.
• Hann Stresemann and Otto Hahn in 1939 proved theoretically that fission of heavy element is possible and the large
amount of energy released can be used in power generation.

5. Nuclear Fission process
• A heavy nucleus is bombarded with slow moving neutrons and two nuclei produced with more neutrons
and high amount of energy is released.
• Let suppose we are considering U-235 as a heavy element. A slow moving electron is set to strike on it
and resulting two lighter nuclei(Ba-144 and Kr-89) produced along with 3 moving neutrons and high
amount of energy which can be denoted as Q.
• The isotope which is used as targeted material is called fissile isotope.

6. Mechanism of Fission process
•The neutron strikes the nucleus and is absorbed.
•The absorbed neutron causes the nucleus to undergo deformation.
•In about 10^(-14) sec, one of the deformation is so drastic that the nucleus cannot recover.
•The nucleus fissions, releasing an average of two to three neutrons.
•In about 10^(-12) sec, the fission fragments lose their kinetic energy and come to rest, emitting a
number of gamma rays. These fragments are called fission products.

7. MECHANISM OF FISSION
PROCESS

8. Some Examples of Nuclear Fission Reaction
Some nuclear fission reactions are as under:
• 235U92 + 1n0 → 137Te52 + 97Zr40 + 21n0 + Q
• 235U92 + 1n0 → 144Ba56 + 89Kr36 + 31n0 + Q
• 235U92 + 1n0 → 148 La37 + 85Br35 + 31n0 + Q
• 239Pu94 + 1n0 → 144Ce58 + 94Kr36 + 21n0 + Q
• 239Pu94 + 1n0 → 134Xe54 + 103Zr40 + 31n0 + Q
In these reactions we see that there are many different products for same element. In a chain
reaction these are all the possibilities of products.
When uranium-235 is bombarded by neutron firstly the products are Ba and Kr but further the
fissile isotopes are Rb and Cs and many more combinations.

9. Fission as a chain mechanism
• The nucleus release high speed neutrons, when bombarded by a neutron.
• The released neutron are then target to surrounding nucleus and split more with more release of neutrons.
• The splitting continues and the reaction is said to be chain reaction. This type of reaction responsible in
explosives.

10. Critical Mass
• In order for a fission chain reaction to occur, the sample of fissionable material must have a certain
minimum mass.
• Otherwise, neutrons escape from the sample before they have the opportunity to strike another
nucleus and cause additional fission.
• The chain stops if enough neutrons are lost.
• The amount of fissionable material large enough to maintain the chain reaction with a constant rate
of fission is called the critical mass.
• When a critical mass of material is present, only one neutron from each fission is subsequently
effective in producing another fission.

11. • The critical mass of uranium-235 is about 1 kg. If more than a critical mass of fissionable material is
present, very few neutrons escape.
• The chain reaction thus multiplies the number of fissions, which can lead to a nuclear explosion.
• A mass in excess of a critical mass is referred to as a supercritical mass.

12. Why we use Uranium-235 and Plutonium?
• The most common isotope, U-238, was not suitable for a nuclear weapon because there is a
fairly high probability that an incident neutron would be captured to form U-239 instead of
causing a fission.
• However, U-235 has a high fission probability as compared to U-238.
• U-235 has abundance of 0.7% in nature. So large amount of uranium was needed to fulfil the
requirements of U-235.
• Also it cannot be separated chemically from U-238 because isotopes are much chemically
similar.
• Recent study had also predicted that plutonium 239 would have a high fission probability.
However, plutonium 239 is not a naturally occurring element and would have to be made.

13. Types of Fission chain process
• There are two types of Fission process:
 Controlled Fission Process
 Uncontrolled Fission Process

14. CONTROL CHAIN
REACTION
• To sustained controlled nuclear reaction, for
every 2 or 3 neutrons released, only one must
be allowed to strike another uranium nucleus.
• Most reactors are controlled by means
of control rods that are made of a strongly
neutron-absorbent material such as boron or
cadmium. ...
• So in order to control the power it is necessary
to introduce non fission nuclear absorption in
the system, example: insert control rods.

16. UNCONTROLLED
CHAIN REACTION
• These types of reactions occurs in nuclear bombs
in which reactions have no control measures.
And this reaction carried out by in absence of
moderator.
• It release large amount of energy at a time.
• This rapid release of nuclear energy causes an
explosion.
• In an uncontrolled chain reaction energy releases
at large amount in a fraction of a second; an 84
trillion joules of energy produces from 22 pounds
or 10 kg of uranium-235 which is highly refined
or the equivalent of 20,000 tons of TNT.

18. Problem with Nuclear Fission Reactions
There are two major problems associated with the system:
• There is always a risk that controls rods would not work in any nuclear reactor
because human errors and failures or sabotage. In this case there is a cause of
explosion or release a large amount of radiations.
• The use fuel is highly radioactive and it must has to be stored over thousands of
years safely. But used fuel is still remains at various power plants in many cases. So
as a result nuclear chain reactions have been decreased in many countries including
in the United States.

19. Advantages of fission process
There are many advantages of fission process implied worldwide. Some are discussed
here:
• Produced heat is converted to electricity.
• With little amount of fuel, large amount of heat is produces.
• 28 gram of uranium produce same amount of energy when 100 metric tons of coal is
used.
• Does not contribute in global warming and causes pollution.
• The waste produced during process is very less.
• The nuclear reactor can support fission process up to 40 to 60 years.

20. Disadvantages of Fission process
There are some negative point of fission reaction:
• Nuclear power reactors are very compact and building cost is very high.
• Reactors require high security.
• Small leakage from reactor can cause explosion.
• Fuel used in process is very expensive and present in trace amounts in nature.
• Possibility of uncontrolled nuclear fission can cause nuclear fallout.

21. Applications of Fission process
There are various applications of nuclear fission:
• Generating electricity.
• Nuclear propulsion system to drive ships or submarines.
• Make neutrons for sensitive Elemental analysis and Industrial use.
• Nuclear weapon.
• Sensitive neutron detector.
• Radioisotopes for industrial use, therapeutic or diagnostic medical purposes.